KR20010064553A - Apparatus to repair and reinforce bridge and thereof method - Google Patents

Abstract

PURPOSE: A bridge repair and reinforcement method is provided to reduce bad influence against the safety of a structure, to construct safely, to prevent the damage of a beam caused by shearing, and to reduce maintenance costs caused by additional repair and reinforcement works. CONSTITUTION: A bridge repair and reinforcement method comprises the steps of installing a square anchoring jacket(200) to both ends of a PC(Pre-Cast) beam(100) in the form of covering the PC beam, fixing a fixture(400) to fix the end of a PC steel wire(500) to a fixing bracket(210) equipped to the square anchoring jacket, straining both ends of the PC steel wire, whose middle is placed over several steel middle saddles installed to the middle bottom of the PC beam and both ends are fixed to the fixture, by a tension gear connected to the fixture of the fixing bracket and re-straining the PC beam.

Description

Bridge repair reinforcement and its method {APPARATUS TO REPAIR AND REINFORCE BRIDGE AND THEREOF METHOD}

The present invention relates to a bridge repair reinforcement device and a method thereof, and in particular, is installed in the form of a "wh" shaped anchoring jacket as a whole to the end of the beam of the pier beams is applied to the bridge with a narrow gap between the beam and beams of the bridge beams The slip guide tube is coupled to the contact portion where the PC strand is in contact with the saddle bracket, and thus the sheath tube of the PC strand can be prevented from being ruptured by friction. A bridge repair reinforcement device and a method for preventing the damage are provided.

In general, bridges have different external factors, such as deflection deformation of beams caused by lack of cross section of existing bridge beams, external vehicles such as larger passing vehicles, and increased traffic volume and aging of bridge beams themselves. As a result, beam stiffness is not only greatly reduced, but cracks and partial breakages occur in bridge structures including these beams, and thus, the risk of unexpected accidents exists in most old bridges.

Therefore, for the aging bridges, the bridge beams with the above-mentioned deflection deformation or stiffness are restored to the original state or to increase the stiffness of each beam in order to prevent accidents, not for emergency repair after an accident. Repair and reinforcement of bridge beams are required.

In the conventional bridge beam repair method as known, a plurality of through holes penetrating the beam in the width direction at both ends of the beam to be repaired in the width direction to embed reinforcing bars in each through hole, and both sides of the beam Frames are formed by weaving a plurality of rebars vertically and horizontally at the ends of each of the rebars exposed to the outside, and then placing concrete on the outside of the reinforcing bars to form a rectangular concrete support. By installing the anchorage to which the steel wires are coupled and tensioning each steel wire fixed in one bundle to the anchorage with a tensioning device, the deflection of the bridge can be corrected by lifting the deformed portion of the beam that sags below the horizontal state. It is known to reinforce rigidity.

However, the conventional repairing method as described above forms a plurality of through holes penetrating the beam in the width direction at both ends of each beam, and embeds a plurality of foundation bars in each through hole, and then the outside of the left and right side walls of the beam. Since many other rebars are vertically and horizontally placed at the end of each reinforcing bar, and concrete is poured into the reinforcing bar frames, such a lot of manpower and long-term It requires a difficult and difficult construction that requires air, and in particular, when forming such a through hole, most of the reinforcing bars and strands that are already longitudinally and horizontally reinforced inside the beam are cut or damaged. As a result of significantly lowering the rigidity of the bridge, problems such as fatal obstacles and defects to the safety of the bridge are rather caused. There was this.

Furthermore, the anchorage according to the conventional repair method is a structure in which a plurality of strands of wire are inserted into a plurality of serrated insertion grooves formed on the outer circumferential surface of one wedge member, and supported in a bundle form. Since it is impossible to expand, it is uneconomical. When one strand of steel is broken, there is a defect and a problem such that the fixed state of the entire steel is loosened or the entire steel is broken so that the safety of work and the efficiency of repair cannot be guaranteed.

Hereinafter, a PC beam retensioning device of a bridge according to the prior art will be described with reference to the drawings.

1 to 2A and 2B are partially cutaway perspective views, side views, and longitudinal cross-sectional views showing a construction example in which the prior art is applied to an I-beam-shaped bridge, and FIG. 3 is a view in which portions of both beams continuously installed are adjacent to each other. Partial enlarged side view showing a construction example, Figure 4 is a perspective view showing the configuration of the steel support bracket for both ends, as shown therein, the bridges to which the prior art is applied is a bridge is arranged at a predetermined distance between the usual two side shifts (1), the PC beam 2 provided continuously over the upper end of each of these piers 1, and the bridge upper plate 3 provided in the upper part of these PC beams 2 are comprised.

The bridge beam repairing apparatus of the present invention is provided with a pair of left and right pairs of steel both ends supporting brackets 10 which are fixed to each end of the longitudinal direction of the PC beam 2, and a predetermined distance between the PC beam 2 and the middle lower side thereof. A plurality of steel intermediate support brackets 20 and 21 and 22 which are fixed and installed, a fixing unit 30 fixedly supported at left and right sides of the steel end support brackets 10, and the steel intermediate support brackets 20: 21, 22 is composed of a plurality of strands of PC strand 40 is supported by the intermediate portion and both ends thereof are fixed in tension by the fixing device (30).

The steel both ends support bracket 10 is a pair of left and right side members 11 and a connection member 12 connected to one end of the left and right side members 11 to be installed in contact with both ends of the PC beam 2. It is constructed so that its entire shape may be "type 1" so as to surround the end of the PC beam 2.

Fastening holes 11a are formed at the front and rear ends of the left and right side members 11, respectively, so that the steel both ends supporting brackets 10 pass through the fastening holes 11a and the work holes 2a of the PC beam 2. Both ends of the steel support brackets 10 may be firmly fastened to both ends of the PC beam 2 by the steel rods 18 which are fastened to each other, and each side member 11 of the steel both ends support brackets 10 may be fastened. It is provided with a plurality of anchor insertion holes (11b) to each of the anchor insertion holes (11b) and the outer wall of the PC beam (2) to a predetermined depth that does not come into contact with the reinforcing bars and steel wires inside the PC beam (2) Both side members 11 are tightly fixed to both side walls of the ends of the PC beam 2 by the lock anchors 13 which are fastened through the formed anchor hole, so that the side members 11 are fixed by the steel bar 18. It is possible to keep the fixed position more stable. The lock anchor 13 is firmly fixed by a conventional anchor cell 14 that is inserted and fixed to the anchor hole of the PC beam (2).

In addition, the left and right side members 11 are provided with a support plate 16 formed with support holes 17 of a predetermined size, and fix both ends of the PC strand 40 to the support holes 17 of the support plate 16. The fixing unit 30 is fixedly installed, and several reinforcing plates 15 are formed on upper and lower ends of the outer surface of the side member 11 and on the inner side thereof.

The steel intermediate support brackets 20:21 and 22 are installed on both sides of the support brackets 21 installed at the middle of the PC beam 2, as shown in FIGS. 1, 2A, and 2B. It consists of the support bracket 22 which becomes.

As shown in FIGS. 5 and 6, the fixing unit 30 includes a steel fixing body 31 fastened by bolts 35 to one surface of the supporting plate 16 of the steel supporting brackets 10. Both ends of each of the PC strands 40 are inserted into and fixed to the steel support 32 and the plurality of support holes 32a provided on the support 32, which are fixed to the stagnation 31 and disposed on the opposite side of the support plate 16. It consists of the several iron collet 33 fixed and fixed.

The collet 33 is configured such that one end of the body divided into three is bound by a binding wire to form a conical body as a whole. The installation quantity of the collet 33 as described above may be increased or decreased according to the required amount of work, that is, the required quantity of the PC strand 40 required for the correction and reinforcement of the PC beam 2.

In FIG. 5, reference numeral P denotes a flexible protective tube for wrapping and protecting a bundle of PC strands 40 exposed between the steel end supporting brackets 10 and exposed to the outside of the PC beam 2.

An example of the repair construction by the conventional bridge beam repair apparatus as described above is as follows.

First, as shown in Figs. 1 to 3, both ends of the steel as the lock anchors 13 fixed to the respective anchor holes are formed by forming a plurality of anchor holes having a predetermined depth on the left and right sides of both ends of the PC beam (2). The left and right side members 11 of the support bracket 10 are fastened and fixed to the left and right sides of the longitudinal ends of the PC beam 2, and the connecting members 12 are welded to the ends of the side members 11 thus formed. The steel both ends support brackets by inserting the steel rods 18 by matching the fastening holes 11a of the steel both ends supporting brackets 10 coupled to the "type 1" and the working holes 2a of the PC beam 2. 10) is firmly fixed to the end of the PC beam (2).

At this time, by welding the "??"-shaped reinforcing rods 42 on the outer surface of the end of the end of both ends of the support bracket 10 as shown in FIG.

After fixing the steel end support brackets 10 as described above, the steel intermediate support brackets 20: 21 and 22 are fixedly installed on both sides of the middle portion of the PC beam 2.

As described above, when the construction of the both ends of the steel support brackets 10 and the intermediate steel support brackets 20: 21 and 22 is completed, the fixing plate 30 of the support plate 16 of the both ends of the steel support brackets 10 may be formed. After fastening and fixing the fixing body 31 and the support body 32, the middle portions of the plurality of PC strands 40 having a predetermined length are supported by the steel intermediate supporting brackets 20: 21, 22, and the respective PC strands 40. Both ends 40a of) are respectively ejected through the fixing unit 30. Thereafter, the collet 33 is coupled to both ends of each of the PC strands 40, and the collet 33 is inserted into the support 32, and the PC strands exposed to the outside of each collet 33 ( At the same time, the end portion 40a of the 40 is held by a conventional tensioning device using hydraulic pressure, and is pulled at a time in the end direction of the PC beam 2, that is, in the direction of “ga” in FIG. 2A.

Pulling each PC strand 40 with a tensioning device as described above is tensioned while the PC strand 40 is guided to the steel intermediate support brackets (20:21, 22), according to the virtual line shown in Figure 2a As shown in the solid line, the PC beam 2, which has been drooped downward, is gradually lifted upward, and is corrected to a horizontal state as shown by a solid line, thereby reinforcing the rigidity of the PC beam 2, such a PC beam ( Correction and reinforcement for the deflection of 2) can be adjusted according to the amount of use and the degree of tension of the PC strand 40.

The bridge beam repair apparatus of the prior art can be applied to various bridge types such as truss bridge, T beam bridge, I beam bridge, PC beam bridge, slab bridge, Gerba bridge, ramen bridge, steel plate bridge, and the like.

However, the bridge beam repair apparatus of the prior art as described above

Fixing the left and right side members 11 of the steel end supporting brackets 10 to the left and right sides of the PC beam 2, and welding the connecting member 12 to the end of the side member 11 as described above. Steel both ends supporting brackets 10 by inserting the steel rods 18 by matching the fastening holes 11a of the both ends of the supporting brackets 10 and the working holes 2a of the PC beam 2 coupled to the 1 " Is fixed to the end of the PC beam (2), and the "c" shaped reinforcing rods 42 are welded to the outer surface of the end portions of the both ends of the support bracket 10, the support force of the both ends of the support brackets (10) After further reinforcing, the end portion of the PC strands 40 is fixed to the fixing fixture 30 fixed to the both ends of the support bracket 10, so that the adjacent PC beams (2), (2) In the narrow bridge between the bridges there was a problem that is very difficult to install the steel support brackets 10.

Furthermore, since there are no gaps between adjacent PC beams 2 and 2 in a bridge constructed by multi-span by spanning three to four PC beams 2, based on both ends of the PC beam 2, There is a problem that the repair and reinforcement of the bridge beam is impossible because it is impossible to install the "type 1" steel end support brackets 10 to be fastened. After multi-span construction, vibration is applied when a high load is applied to the slab. Due to this, there is a problem in that the bridge is applied to the continuum connection to damage the bridge.

In addition, conventionally, the sheath pipe for protecting the stranded wire when reinforcing the PC beam external steel wire of the bridge is made of saddle-kit and stop jacket, while the material of the sheath pipe is made of synthetic resin (PE). There is a problem that the sheath tube is broken and the external leakage of the grease filled inside and the damage of the stranded wire are generated.

For the new and improved technology than the prior art, if the gap between the beam and the beam is not secured or the reinforcement part is not secured, the fixing end should be installed by drilling the beam end or cutting or drilling the beam composite part, thereby damaging the structure accordingly. There is a need for new construction techniques to be applied to repair and reinforcement methods.

In addition, the sheath pipe that protects the steel wire during PC beam steel wire reinforcement work is damaged due to the difference between the metal material and the synthetic resin (PE) material at the contact portion between the fixing jacket and the saddle bracket. It is necessary to compensate for defects such as the outflow of grease filled in the tank.

In addition, if the slab is continuously multi-span by the slab continuous method of the bridge, the parental phenomenon occurs in the continuous connection due to external requirements such as the progress of heavy vehicles, which may cause unstable elements such as cracks in the upper part of the bridge. Measures to ensure the safety of the

In addition, earthquake disasters in many countries have attracted attention on earthquake-resistant design, but existing bridges are not well prepared for earthquake-proofing due to weak seismic review. And apparatus.

Therefore, the present invention was devised to solve and compensate for all the problems and defects of the related art as described above. Even when the gap between the beam and the beam is not secured during the repair and reinforcement of the bridge beam, the " It is an object of the present invention to provide a bridge repair reinforcement device and a method for repairing and reinforcing a structure without damaging the structure using a jacket.

Another object of the present invention is to provide a bridge repair reinforcement apparatus and its method that can be used stably without damage by combining the slip guide tube in contact with the sheath tube to protect the steel wire during PC beam steel wire reinforcement work will be.

It is still another object of the present invention to provide a bridge repair reinforcement device and a method of installing the anti-mention preventing device for preventing the parent-ment phenomenon in the connection portion of the long span slab to secure the safety of the structure.

It is still another object of the present invention to provide a bridge repair reinforcement apparatus and a method of reducing damage of a bridge and increasing durability when an external pressure such as an earthquake occurs.

1 to 6 is a view showing the configuration of a conventional bridge beam repair device,

1 is a partially cutaway perspective view.

2A is a side view.

2B is a longitudinal sectional view.

3 is a partially enlarged side view

Figure 4 is a perspective view showing the configuration of both ends of the support brackets.

5 is a perspective view of the fixing unit.

6 is a plan view of the fixing unit;

7 to 14 show the configuration of the bridge beam repair apparatus according to an embodiment of the present invention,

7 is a partially cutaway perspective view.

8A is a partially cutaway enlarged perspective view.

8B is a partially cut-away enlarged plan view.

9 is a perspective view of a fixing bracket.

10 is a cross-sectional view taken along the line A-A of FIG.

11 is a front view showing a PC beam re-tensioning PC strands on the second saddle and the PC strands for preventing the anti-mentum is fixed.

12 is a cross-sectional view taken along the line B-B in FIG. 7.

FIG. 13 is a front view showing a form in which a PC strand for PC beam retension is spread over a first saddle; FIG.

14 is a perspective view of the parental preventing birds.

15 and 16 are a perspective view and a plan view showing the configuration of the bridge beam repair apparatus according to another embodiment of the present invention.

17 to 21 is a view showing the configuration of the bridge beam repair apparatus according to another embodiment of the present invention,

17 is a partially cutaway perspective view.

18 is a partially cut-away enlarged perspective view.

19 is a partially cut-away enlarged plan view.

20 is a cross-sectional view taken along the line C-C in FIG.

Figure 21 is a front view showing the form of the PC strand on both ends of the simple saddle.

22 and 23 are a partially cutaway perspective view and a plan view of a bridge beam repair apparatus according to another embodiment of the present invention.

<Description of the reference numerals for the main parts of the drawings>

100: pier 110: PC beam

110a: spare part 111: upper surface

112: anchor bar 112a: vertical portion

130: chair device 200: "ㅁ" shaped settled jacket

201: side plate 202: bottom plate

203: top plate 203a, 204a: fastening portion

203b: fixing hole 210: fixing bracket

300: middle steel saddle 300: 310,320: middle steel saddle

310: first birds 320: second birds

314: guide support groove 321: side plate

322: bottom plate 323: information plate

324: guide support groove 325: reinforcement plate

400: anchorage 500: PC strand for PC beam retension

500 ': PC strands to prevent parental 520: slip guide tube

520: outer slip guide tube 521: inner slip guide tube

600: saddle prevention saddle 601: fixed plate

601a: fixing hole 602: information board

603: guide support groove 604: reinforcement plate

In order to achieve the above object, the bridge repair reinforcement device according to the present invention is fixed to each of the "ㅁ" shaped fixing jackets and is fixed to each of the "ㅁ" shaped fixing jackets so as to surround the PC beams at both ends of the PC beams. Brackets are fixed to each other, and fixing fixtures are fixed to the fixing brackets, respectively, for fixing the two end portions of the PC strand in which the middle portion is stretched to a plurality of steel intermediate saddles installed in the middle lower portion of the PC beam.

The "ㅁ" shaped fixing jacket is formed of, for example, an upper surface plate coupled to the upper surface portion of the PC beam, side plates coupled to the left and right sides of both ends, and a lower surface plate coupled to the lower surface, and these upper surface plates, both side plates, and The bottom plate is fixed to the PC beam by an anchor, and the connecting portion is welded. The upper and lower plates are integrally bent at both ends of the upper and lower plates so that the upper and lower ends of the both side plates are overlapped and welded to the outer sides of the upper and lower ends of the side plates. It is formed so that the upper surface plate is firmly fixed by relying on the vertical portion of the reinforcing bar by inserting and coupling the vertical portion of the anchor reinforcing bar protruded to the upper surface portion of the PC beam.

The "ㅁ" shaped fixing jacket is formed to wrap around a certain width from the end of the PC beam, and is formed to wrap around a certain width leaving a margin of a certain distance from the end of the PC beam do. In addition, the bottom plate of the "ㅁ" shaped fixing jacket is provided between the lower surface of the PC beam and the seating device, and the bottom plate of the "ㅁ" shaped fixing jacket is located inside the seating device on the lower surface of the PC beam. It is configured in such a way that it is installed.

On the other hand, both side panels of each "ㅁ" shaped fixing jacket, the birds are fixed to each other to prevent the parent, so that the PC strand is stretched, and the fixing bracket is fixed to the second saddle, respectively, each fixing bracket The fixing device for fixing both ends by tensioning the PC strand is configured to be fixed.

The anti-cement saddle is, for example, the guide plate is welded to the upper end of the fixed plate fixed to the side plate of the "ㅁ" shaped fixing jacket of the both ends to form a guide support groove and a plurality of reinforcement plate is welded to the side of the fixing plate, The guide support groove is formed in a shape having a horizontal portion and an inclined portion, and the fixing plate is formed by forming a plurality of fixing holes for anchoring. More specifically, the anti-mentor saddle is disposed on the upper side of the inner side of the side plate of the "ㅁ" shaped anchoring jacket, the anchoring bracket for preventing the parent-ment distance in the longitudinal direction and the width direction relative to the anti-cement saddle Is disposed on the side plate of the second saddle so as to be positioned below the configuration is configured so that the PC strands across the anti-cement saddle and the fixing bracket is inclined downward.

The second birds of the steel intermediate birds are the side plate fixed to the left and right sides of the PC beam and the bottom plate fixed to the lower surface is welded and fixed, the guide plate is welded to both sides of the lower plate to form a guide support groove A plurality of reinforcing plates are welded, and the fixing brackets are fixed to the side plates, respectively.

Fixing bracket for preventing anti-mention is directly fixed to the side plate of the "ㅁ" shaped fixing jacket, the end of the PC strand is fixed to the fixing fixture fixed to both fixing brackets are configured to be directly tensioned.

Fixing bracket for preventing the anti-mention on the side plate of the "ㅁ" shaped fixing jacket, which is provided with a "ㅁ" shaped fixing jacket, leaving a margin of a predetermined width from the end of the PC beam, and fixed to both ends of the PC beam. The kit is directly fixed, and the end of the PC strand is directly fixed to the fixing fixture which is fixed to both fixing brackets.

The PC strand is coupled to the guide guide groove of the steel intermediate birds and the guide support groove of the anti-cement saddle is coupled to the slip guide pipe is configured to smoothly slip.

The slip guide tube is a stainless pipe that is doublely coupled, and the inner slip guide tube is formed to be longer than the outer slip guide tube is configured to protrude as much as the margin along the flow to both sides of the outer slip guide tube.

Such bridge repair reinforcement method of the present invention can be widely used in various bridges, such as ordinary slab bridges, and in particular, it can be very advantageous to repair and reinforce the PC beam of the narrow portion between the slab continuum beam and the beam. As a device and a construction method, it is possible to construct without damaging the structure of the bridge, it can greatly contribute to securing safety by reducing the cost of re-establishment and reconstruction of the structure when connected in conjunction with the bridge slab sequencing method.

Hereinafter, the embodiments of the present invention will be described in detail with reference to the accompanying drawings.

7 to 14 is a view showing the configuration of the bridge beam repair apparatus according to an embodiment of the present invention, Figure 7 is a partial cutaway perspective view, Figure 8a partially cutaway enlarged perspective view, Figure 8b partially cutaway enlarged plan view, Figure 9 The anchoring brackets are shown, respectively, FIG. 10 is a cross-sectional view taken along the line AA of FIG. 7, and FIG. 11 is a front view showing the PC beam retensioning line being stretched on the second saddle and the PC strands for preventing the momentum being fixed. FIG. 12 is a cross-sectional view taken along line BB of FIG. 7, and FIG. 13 is a front view of a PC beam retightening line extending over a first saddle, respectively, and FIG. 14 is a perspective view of birds for preventing a parent moment. have.

As shown in the drawing, reference numeral 100 denotes a pier, 110 denotes a PC beam, 200 denotes a "ㅁ" shaped fixing jacket, and a plurality of pier devices 130 on the upper ends of the pier 100. Is installed, a plurality of PC beams 110 are continuously coupled over the bridge device 130, and the "x" shaped fixing jacket 200 is fixed to each of the longitudinal ends of the PC beam 110, respectively, Each " W " shaped fixing jacket 200 is provided with a fixing bracket 210.

A plurality of steel intermediate saddles 300: 310 and 320 are fixedly installed at predetermined intervals in the middle lower portion of the PC beam 110, and the fixing holes are provided in the left and right fixing brackets 210 of the “ㅁ” shaped fixing jacket 200. 400 is fixed, and both ends of the PC strand 500 which is supported by the steel intermediate saddles 300: 310 and 320 are fixed in a tensioned state by the fixing unit 400.

As shown in FIGS. 8A and 8B, the "ㅁ" shaped fixing jacket 200 includes side plates 201 coupled to the left and right sides of the PC beam 110, a lower plate 202 coupled to the lower surface, and an upper surface thereof. It is formed as a top plate 203 to be coupled is fixed in a form surrounding the PC beam (110).

The upper and lower plates 203 and 202 have the fastening portions 203a and 204a integrally bent at both ends, so that the fastening portions 203a and 204a are formed at the upper and lower ends of both side plates 201. By overlapping and welding, the upper and lower plates 203 and 202 and both side plates 201 form a single “?” Shaped fixing jacket 200.

A plurality of fixing holes 203b are formed in the upper plate 203 of the “ㅁ” shaped fixing jacket 200 to form a vertical portion 112a of the reinforcing bar 112 protruding from the upper surface 111 of the PC beam 110. The top plate 203 is firmly fixed by relying on the vertical portion 112a of the reinforcing steel 112 by insertion.

When the upper surface portion 111 of the PC beam 110 is cut to a predetermined thickness, a plurality of reinforcing bars 112 already embedded when the PC beam 110 is manufactured are exposed, and the horizontal portion 112b of each of the reinforcing bars 112 is exposed. ), The vertical part 112a is left after cutting, thereby fixing the upper plate 203 as above using the vertical part 112a.

A plurality of fixing holes 201a are formed in both side plates 201, and fixing holes 111a corresponding to the left and right sides of the PC beam 110 are formed to communicate with each other. In addition, the anchor is fixed to the upper and lower plates 203 and 202, and the anchoring portions 203a and 204a of the upper and lower plates 203 and 202 and the upper and lower portions of the side plate 201 are attached to the anchor. By fixing, both side plates 201 and the upper and lower plates 203 and 202 are firmly fixed by the vertical portions 112a, anchors and welding of the reinforcing bars 112.

As shown in FIGS. 7, 12, and 13, the first saddle 310 of the steel intermediate saddles 300: 310 and 320 may be disposed on the side plates 311 and the bottom surface of the steel intermediate saddles 300, 310, and 320. The fixed bottom plate 312 is welded and fixed, and guide plates 313 are fixed to lower ends of both side plates 311 to form guide support grooves 314 and a plurality of reinforcement plates 315 are welded. And fixed to the PC beam 110 by a plurality of anchors.

As shown in FIGS. 7, 10, and 11, the second saddle 320 of the steel intermediate saddles 300: 310 and 320 has side plates 321 fixed to left and right sides of the PC beam 110, and bottom surfaces thereof. The lower plate 322 is fixed to the weld is fixed, the guide plate 323 is welded to both side edges of the lower plate 322 to form a guide support groove 324 and a plurality of reinforcement plate 325 is welded It is fixed to the PC beam 110 by a plurality of anchors.

The epoxy concrete 120 is filled between the side plate 321 of the second saddle 320 and the concave portion 113 of the PC beam 110 to achieve a stronger bond.

The fixing bracket 210 is fixed to the left and right sides of the " '&quot; shaped fixing jacket 200, as shown in Figs. 8 and 9, across both side members 211 and both longitudinal members 211 on both side plates 201. The horizontal member 212 and the reinforcing member 213 to be joined are welded, and the horizontal member 212 has a fixing hole 214 to which the fixing unit 400 is fixed.

The PC strand 500 is composed of a plurality of strands, for example, D12.7mm 7 strand strand 501 is covered with a sheath tube 500 ', the inside of the sheath tube 500' such as grease Lubricants can be injected and used.

Wherein the PC strand 500 is inserted into the guide supporting grooves 314, 324 of the steel intermediate saddle (300: 310, 320) is inserted into the slip guide pipe 520, 521 is coupled to the PC strand 500 It slips and can move smoothly.

For example, stainless pipes are used for the slip guide tubes 520 and 521. In addition, the inner slip guide tube 521 is formed longer than the outer slip guide tube 520 and protrudes as much as the margin along the flow to both sides of the outer slip guide tube 520.

As shown in FIGS. 7 and 8A and 8B, the non-contraction mortar layer 140 is poured between end portions of the adjacent PC beams 110.

In addition, the reference numeral 600 in FIGS. 7 and 8 shows the anticement prevention birds, and the anticement prevention saddle 600 is fixed to both side plates 201 of the “ㅁ” shaped fixing jacket 200 at both ends, respectively. The PC strand 500 'is spanned, the fixing brackets 210 are fixed to the second saddle 320, respectively, and the PC strand 500' is fixed to each fixing bracket 210 at both ends thereof. A fixing unit 400 for fixing is fixed.

As shown in FIGS. 8 and 14, the anti-cement saddle 600 may include a guide plate 602 at an upper end of a fixing plate 601 fixed to the side plate 201 of the “ㅁ” shaped fixing jacket 200 at both ends. ) Is welded to form a guide support groove 603 and a plurality of reinforcement plates 604 are welded to the side surface of the fixed plate 601. The guide support groove 603 has a horizontal portion and an inclined portion. It is formed in a shape, and a plurality of fixing holes 601a for fixing the anchors are formed in the fixing plate 601.

The anchorage preventing fixing bracket 210 is formed on the side plate 321 of the second saddle 320 in the same configuration as the fixing bracket 210 for re-tension as shown in FIG. 9. That is, the side plate 201 of the second saddle 320 is formed in the same shape, instead of the side plate 201 of the “ㅁ” shaped fixing jacket 200.

The anti-cement saddle 600 and the anti-cement fixing bracket 210 are the side plate of the "ㅁ" shaped fixing jacket 200 in consideration of the ease of manufacturing and construction work, the anti-cement force, mechanical strength, etc. 201 and the side plate 321 of the second saddle 320 are preferably formed together, but may be installed independently at different positions.

In the form in which the anti-cement saddle 600 and the fixing bracket 210 are installed together on the side plate 201 of the “ㅁ” shaped fixing jacket 200 and the side plate 321 of the second saddle 320. In FIG. 8A, the anti-mentor saddle 600 is disposed on the upper side of the inner side of the side plate 201 of the " W " shaped fixing jacket 200, and the anti-mentor fixing bracket 210 is a parent-ment. The anti saddle 600 and the fixing bracket 210 are disposed on the side plate 321 of the second saddle 320 so as to be positioned at a lower distance with respect to the prevention saddle 600 in the longitudinal direction and the width direction. PC stranded wire 500 'is installed to be inclined downward.

And, in the case of installing the parental prevention device as shown in Figure 11 the reinforcing support plate 330 for reinforcing both sides of the lower side of the side plate 321 of the second saddle 320 to the PC beam 110 as an anchor. Fix it.

Bridge repair reinforcement method using the "wh" shaped fixing jacket of the present invention as described above, as shown in Figures 7 and 8, after cutting the slab of the pier part of the PC beam 110, and then crushed the beam upper reinforcement Expose (112).

Thereafter, the horizontal portion 112b of the exposed rebar 112 is cut as many times as necessary.

Thereafter, the upper plate 203 is coupled to the upper surface of the PC beam 110 so that the vertical portions 112a of the reinforcing bars 112 are inserted into the plurality of fixing holes 203b.

Subsequently, both side plates 201 having the fixing brackets 210 are coupled to the left and right sides of the PC beam 110 to be fixed by anchors, and the top plate 203 and both side plates 201 are welded.

After that, the lower surface plate 202 is installed on the lower surface of the PC beam 110 and welded to both side plates 201 to fix the shape of ". &Quot;

In addition, the fixing bracket 210 is coupled to the fixing bracket 210 of the “ㅁ” shaped fixing jacket 200, and the first middle of the steel intermediate saddles 300: 310 and 320 is disposed at the middle of the left and right sides of the PC beam 110. The saddle 310 is fixed, and the second saddle 320 is fixed to both sides of the first saddle 310, respectively.

As described above, when the construction of the "ㅁ" shaped fixing jacket 200 having the fixing bracket 210 and the steel intermediate saddles 300: 310 and 320 is completed, the first saddle of the steel intermediate saddles 300: 310 and 320 ( After coupling the slip guide tubes 520 and 521 to 310 and the second saddle 320, the middle portion of the PC strand 500 is inserted and fixed.

Subsequently, the reinforcing bar is welded to the reinforcing bar 112 on the upper portion of the PC beam 110, and the upper slab reinforcing bar is welded.

Subsequently, an epoxy putty operation is performed around the top plate 203, both side plates 201, and the bottom plate 202 of the ". &Quot; shaped fixing jacket 200, and epoxy is injected.

After that, the formwork is installed under the upper slab cut part, the old and new concrete adhesive is applied to the crushing part, and then the concrete is poured to cure and asphalt pavement.

When the epoxy is hardened to a certain strength or more, the hydraulic jack for tension is installed in the fixing bracket 210 of the “ㅁ” shaped fixing jacket 200.

Thereafter, the ends of each of the PC strands 500 exposed to the outside of the anchoring device 400 are simultaneously grasped and fixed with a tensioning device, and the structural review demand strength pressure is applied to both ends of the PC strands 500 at both ends of the PC beam 110. By pulling at a time, the PC beam 110, which has been drooped in the lower state, is corrected to a horizontal state, and the rigidity is reinforced, and antirust grease is injected into the sheath pipe 510 of the PC strand 500. After cutting the PC strand 500 to the length that can be re-tension, the protective cap is installed to take protective measures.

Subsequently, epoxy paint is applied to the entire reinforcement part to prevent rust and finish.

On the other hand, if you want to install the anti-mentor device with the PC beam re-tensioning device as needed, when the "ㅁ" shaped fixing jacket 200 when manufacturing the saddle 600 for the anti-mentor to the side plate 201 Formed together, and formed by installing the fixing bracket 210 together on the side plate 321 of the second saddle 320, and the anti-mentoral saddle formed in the "ㅁ" shaped fixing jacket 200 of both ends ( PC stranded wire 500 'hanging on the PC strand 500' and fixed to both ends of the PC stranded wire 500 'to the fixing bracket 210 formed on the second saddle 320, the PC strand wire protruding out of the fixing bracket 210 The end of 500 'is tensioned by a tensioning device to exert a structural review demand strength pressure to tension it outward in both directions, thus preventing damage to the bridge due to parenting occurring in the multi-span continuous slab.

As shown above, the PC strands 500 'are fastened to the anti-mention saddles 600 and 600 installed at both ends of the PC beam 110 adjacent to each other, and the fixing holes of the fixing bracket 210 installed at a distance in an inclined direction ( When both ends of the PC strand 500 'are pulled using 400, both ends of the PC beams 110 adjacent to each other are pulled to each other to act as a resistance force against the parent moments while receiving a compressive force. In addition, since both ends of the PC beam 110 adjacent to each other is pulled by the PC strand (500 ′) for preventing the parent cement to have a binding force, the left and right flow of the PC beam 110 is prevented, and external factors such as earthquakes are prevented. Falling of the slab caused by the effect is prevented and durability is increased.

15 and 16 are a perspective view and a plan view showing the configuration of the bridge beam repair apparatus according to another embodiment of the present invention, the embodiment is the "x" shaped anchoring jacket 200 is the end edge of the PC beam 110 It is installed in the form of wrapping up, but in this other embodiment is configured to install a "ㅁ" shaped fixing jacket 200, leaving the spare portion 110a of a predetermined width from the end of the PC beam 110, Thus, the "ㅁ" shaped fixing jacket 200 of one embodiment is formed with a long width based on its inner side, and the "ㅁ" shaped fixing jacket 200 of another embodiment has a short short width based on its inner side Formed.

In addition, in the embodiment of the “ㅁ” shaped fixing jacket 200, the bottom plate 202 is installed on the bridge device 130 installed between the piers 100 and the PC beam 110. "The fusing jacket 200 has a structure in which the lower plate 202 is provided as the side of the chair device 130.

17 to 22 are views showing the configuration of a bridge beam repair apparatus according to another embodiment of the present invention, FIG. 17 is a partially cutaway perspective view, FIG. 18 is a partially cutaway enlarged perspective view, and FIG. 19 is a partially cutaway enlarged plan view, respectively. FIG. 20 is a cross-sectional view taken along line CC of FIG. 17, and FIG. 21 is a front view showing a form in which PC strands for tensioning a PC beam are stretched on both ends of a simple saddle.

Bridge repair reinforcement device according to another embodiment of the present invention shown in this is fixed to the side plate 201 of the "ㅁ" shaped fixing jacket 200 fixed to both ends of the PC beam 110 fixing bracket ( 210 is directly fixed and fixed to the fixing unit 400 fixed to both fixing brackets 210 to the ends of the PC strand 500 'by direct tension to prevent the parent of the adjacent PC beam 110 is configured to It is.

Accordingly, although the fixing bracket 210 is formed in the second saddle 320 of FIG. 11 to fix the fixing unit 400 for tensioning the PC strand 500 ', the fixing saddle 210 is formed here. As the fixing saddle 210 does not need to be provided in the second saddle 320, the second saddle 320 is formed in a simple shape.

17 to 21 illustrate the parent of the PC beam 110 by fixing both ends of the PC strand 500 'to the fixing bracket 210 installed at both ends of the PC beam 110 adjacent to each other. In addition to preventing the flow and falling of the PC beam 110 and the like, the construction work is simpler, and can be used more conveniently when only the parental prevention device is installed independently. Of course, the fixing bracket 210 of the parental prevention device is preferably installed in the "ㅁ" shaped fixing jacket 200, may be directly fixed to the PC beam 110 or may be installed in other forms.

22 and 23 show a partially cutaway perspective view and a plan view of a bridge beam repair apparatus according to another embodiment of the present invention, which is the embodiment of FIGS. 17 to 21 and FIGS. 15 and 16. As an embodiment combining the embodiments, the ". &Quot; shaped fixing jacket 200 is provided with a marginal portion 110a of a predetermined width from the end of the PC beam 110, while the PC beam 110 is provided. Directly fixing the fixing bracket for preventing the anti-mention 210 to the side plate 201 of the "ㅁ" shaped fixing jacket 200 fixed to both ends, the PC to the fixing unit 400 fixed to both fixing brackets 210 By fixing the ends of the strand 500 'directly and directly tensioning, it is configured to prevent the parent moment of the adjacent PC beam 110.

Other configurations and operations of the embodiment shown in FIGS. 22 and 23 are similar to those of FIGS. 17 to 21 and those of FIGS. 15 and 16.

The present invention as described above can be applied to the bridge is difficult to install the existing anchoring jacket because the gap between the beam and the beam of the pier is narrow, compared to other construction methods such as drilling the side of the beam It can reduce the adverse effect on safety and construct safely, and it covers the end of the beam of the pier as a whole, and it performs the function of shear reinforcement to prevent the damage of the beam due to shear, and maintenance cost due to additional repair and reinforcement. Can reduce the cost.

In addition, since the slip guide tube is coupled to the contact portion where the PC strand is in contact with the saddle bracket, the PC strand is lubricated so that the sheath tube is not ruptured due to friction, and the inner filling grease of the sheath tube is damaged. This prevents external spillage and damage to the stranded wire, reducing maintenance and repair costs, while minimizing the loss of tensile forces due to friction. In addition, the use of stainless pipes in the slip guide tube is advantageous in appearance and eliminates the need for a separate rust-preventive coating process, and also absorbs the frictional force in the double-installed stainless steel pipe itself, thereby preventing the lateral load on the saddle bracket. The effect of PC beam stiffness reinforcement can be enhanced.

In addition, the anti-mentoring method is a multi-span continuous slab method for the safety of the bridges. When high loads are applied to the vehicle traffic during heavy loads during construction, the parent moments are generated in the slab continuity, causing damage to the bridges, and the safety of the bridges. It is possible to prevent the problem that causes enormous obstacles in the system, and to reduce the maintenance and repair costs due to the damage of the bridge due to the parental cement. The parental cement preventive device is equipped with the PC beam retensioning technique using the "ㅁ" shaped fixing jacket. If it is connected in construction, it can be installed without a separate hypothesis, which is effective in reducing the cost. In addition, by acting as a link between the slab and the slab to prevent damage to the piers and sinking of the slab at the foundation of the foundation due to external factors such as earthquakes, it is effective in the earthquake preparedness.

Claims (20)

Fixing brackets 200 are fixedly installed at both ends of the PC beam 110 in a form of enclosing the PC beams 110, respectively, and fixing brackets 210 are formed at the respective “ㅁ” shaped fixing jackets 200. Are fixed to each other, and the fixing unit 400 for tensioning and fixing both ends of the PC strand 500 having an intermediate portion in the plurality of steel intermediate saddles 300: 310 and 320 installed in the middle lower portion of the PC beam 110 is provided. Bridge repair reinforcement, characterized in that configured to be respectively fixed to the fixing bracket (210). According to claim 1, wherein the "ㅁ" shaped fixing jacket 200 is a top plate 203 is coupled to the upper surface portion of the PC beam 110, side plates 201 are coupled to the left and right sides of both ends, and It is formed by the bottom plate 202 to be coupled, these top plate 203, both side plates 201 and the bottom plate 202 is fixed to the PC beam 110, and the connection portion is characterized in that the welded configuration Bridge repair reinforcement. The upper and lower plates 203 and 202 of the upper and lower plates 204a and 204a are integrally bent at both ends to fasten the upper and lower ends of both side plates 201. The bridge repair reinforcement, characterized in that the (204a) is overlapped to the outside and welded. The anchor plate of claim 1, wherein a plurality of fixing holes 203b are formed in the top plate 203 of the “ㅁ” shaped fixing jacket 200 to protrude from the top surface 111 of the PC beam 110. Bridge repair reinforcement device, characterized in that the top plate (203) is fixed by the vertical portion (112a) of the reinforcing bar 112 by inserting the vertical portion (112a) of the (112). The bridge repair reinforcement device according to claim 1, wherein the "x" shaped fixing jacket (200) is formed to cover a predetermined width from an end of the PC beam (110). According to claim 1, wherein the "ㅁ" shaped fixing jacket 200 is characterized in that it is formed to wrap around a predetermined width leaving a marginal portion (110a) of a certain distance from the end of the PC beam (110) Bridge repair reinforcement. The bridge repair reinforcement according to claim 1, wherein the lower plate 202 of the ". &Quot; shaped fixing jacket 200 is installed between the lower surface of the PC beam 110 and the bridge device 130. Device. 2. The bridge repair reinforcement of claim 1, wherein the bottom plate 202 of the ". &Quot; shaped fixing jacket 200 is installed on the bottom surface of the PC beam 110 so as to be positioned inside the bridge device 130. Device. According to claim 1, wherein each side of the "ㅁ" shaped fixing jacket 200, both sides of the side plate 201 is fixed to the anti-cement saddle 600, respectively, so that the PC strand (500 ') spans, the second Fixing brackets 210 are fixed to the saddle 320, respectively, and each fixing bracket 210 is characterized in that the fixing fixture 400 for fixing both ends by tensioning the PC strand 500 'is characterized in that it is configured Bridge repair reinforcement. 10. The guide plate 602 is welded to the upper end of the fixing plate 601 fixed to the side plate 201 of the " '&quot; shaped fixing jacket 200 at both ends. A guide support groove 603 is formed and a plurality of reinforcement plates 604 are welded to side surfaces of the fixed plate 601, and the guide support groove 603 is formed in a shape having a horizontal portion and an inclined portion, and the fixed plate ( 601) bridge repair reinforcement, characterized in that a plurality of fixing holes (601a) for driving the anchor is formed. 10. The method of claim 9, wherein the anti-cement saddle 600 is disposed on the upper side of the inner side of the side plate 201 of the "ㅁ" shaped fixing jacket 200, the fixing bracket for preventing the parent cement 210 Is disposed on the side plate 321 of the second saddle 320 at a distance in the longitudinal direction and the width direction relative to the anti-cement saddle 600 is fixed to the anti-cement saddle 600 Bridge repair reinforcement device characterized in that the PC strand (500 ') spanned over the bracket 210 is configured to slope downward. 10. The method of claim 9, wherein the second saddle 320 of the steel intermediate saddle 300 is a side plate 321 fixed to the left and right sides of the PC beam 110 and the bottom plate 322 is fixed to the lower surface Welded and fixed, the guide plate 323 is welded to both side edges of the lower plate 322 to form a guide support groove 324 and a plurality of reinforcement plate 325 is welded, the side plate 321 is Bridge repair reinforcement device, characterized in that the fixing bracket for fixing the parent anchorage fixing device 400 is configured to each fixed. The fixing bracket 400 of claim 1, wherein the fixing bracket 210 for preventing the parental cement is directly fixed to the side plate 201 of the “ㅁ” shaped fixing jacket 200 and fixed to both fixing brackets 210. Bridge repair reinforcement device, characterized in that the end of the PC strand (500 ') is fixed to direct tension). The method of claim 13, wherein the "x" shaped fixing jacket 200 is provided leaving the marginal portion (110a) by a predetermined width from the end of the PC beam 110, the both ends of the PC beam (110) The fixing bracket 210 for preventing the anti-mention is directly fixed to the side plate 201 of the “ㅁ” shaped fixing jacket 200 to be fixed, and the fixing unit 400 is fixed to both fixing brackets 210. Bridge repair reinforcement device, characterized in that the end portion of the PC strand (500 ') is directly fixed. The guide support groove 603 of claim 1 or 9, wherein the PC strand 500 is guide supporting grooves 314 and 324 of the steel intermediate saddles 300: 310 and 320 and the saddle preventing saddle 600. Slip guide pipe 520, 521 is coupled to the bridge repair reinforcement, characterized in that the PC strand 500 is configured to smoothly slip. 16. The slip guide tube of claim 15, wherein the slip guide tubes 520 and 521 are stainless pipes which are double-coupled, and the inner slip guide tube 521 is formed longer than the outer slip guide tube 520, Bridge repair reinforcement, characterized in that configured to project as much as the margin along the flow to both sides of (520). Installing the "ㅁ" shaped fixing jacket 200 in the form of wrapping the PC beam 110 at both ends of the PC beam 110, and fixing brackets provided in the respective "ㅁ" shaped fixing jackets 200, respectively. Fixing the fixing unit 400 for fixing the end of the PC strand 500 to 210, and the middle portion in the plurality of steel intermediate saddles (300: 310, 320) installed in the lower middle of the PC beam 110 The PC beam 110 including tensioning both ends of the PC strand 500 that is stretched and fixed at both ends to the fixing unit 400 by a tensioning device connected to the fixing unit 400 of the fixing bracket 210. Bridge reinforcement method characterized in that the re-tension. 18. The method of claim 17, wherein when forming the "k" shaped fixing jacket 200, the side plate 201 together with the anti-cement saddle 600 is formed together, the side plate 321 of the second saddle 320 Forming the fixing bracket 210 together to install the "ㅁ" shaped fixing jacket 200 and the second saddle 320, and the fixing hole in the fixing bracket 210 of the second saddle 320 The step of installing the 400, and the fastening holes 400 of the fixing bracket 210 by hanging the PC strand 500 'to the anti-mention saddle 600 formed in the "ㅁ" shaped fixing jacket 200 of both ends Fixing both ends of the PC strand 500 'to the tension device, and tensioning both ends of the PC strand 500' with the tensioning device connected to the anchorage 400 of the fixing bracket 210. Bridge repair reinforcement method characterized in that it prevents the parent moment of the PC beam 110, and prevents left and right flow and falling. 18. The method according to claim 17, wherein the slab of the pier portion of the PC beam 110 is cut and broken to expose the beam upper reinforcing bars 112, and the horizontal portion 112b of the exposed reinforcing bars 112 is required. Cutting as much as possible, and coupling the top plate 203 to the upper surface portion of the PC beam 110 such that the vertical portion 112a of the reinforcing rod 112 is inserted into the plurality of fixing holes 203b thereof. Fixing both side plates 201 having the fixing brackets 210 to the left and right sides of the PC beam 110 by fixing them with anchors, and welding the top plates 203 and both side plates 201 by welding. And installing a lower surface plate 202 on the lower surface of the PC beam 110 and welding the both side plates 201 to fix it in a shape of "ㅁ", and the "ㅁ" shaped fixing jacket 200. A fixing bracket 400 is coupled to the fixing bracket 210, and the first saddle 310 of the steel intermediate saddles 300: 310 and 320 is attached to the middle of the left and right sides of the PC beam 110. And fixing second saddles 320 on both sides of the first saddle 310, and slipping the first saddle 310 and the second saddle 320 of the steel intermediate saddles 300, 310, and 320. After combining the guide pipes 520 and 521, fixing the PC strand 500, and connecting the reinforcing bars to the reinforcing bars 112 of the upper portion of the PC beam 110, the upper slab reinforcement Welding, and performing epoxy putty work and injecting epoxy around the top plate 203, both side plates 201, and the bottom plate 202 of the “ㅁ” shaped fixing jacket 200; Installing a formwork below the upper slab cut portion of the beam 110, and applying the old and new concrete adhesive to the crushing part, and then curing by placing concrete and asphalt pavement, when the epoxy is hardened to a certain strength or more the " ㅁ "step of installing the hydraulic jack for tension in the fixing bracket (210) of the shaped fixing jacket (200) And simultaneously hold and fix an end portion of each PC strand 500 exposed to the outside of the anchorage 400 with a tensioning device, and apply pressure to tension both ends of the PC strand 500 in both directions outside of the PC beam 110. And the step of injecting antirust grease into the sheath pipe 510 of the PC strand 500, cutting the PC strand 500 into a length capable of retension, and installing a protective cap. Protecting and by applying epoxy paint to the entire reinforcement, and performing a rustproof treatment and finishing. 20. The method of claim 19, wherein when forming the "ㅁ" shaped fixing jacket 200, forming a saddle prevention saddle 600 in the side plate 201 together with the side plate (2) of the second saddle 320 321 and the installation of the fixing bracket 210 together with the installation, and the PC stranded wire 510 'hanging on the anti-mention saddle 600 formed in the "ㅁ" shaped fixing jacket 200 of the both ends 2 PC strands 510 'protruding to the outside of the fixing bracket 210 by fixing both ends of the PC strand 510' to the fixing unit 400 coupled to the fixing bracket 210 of the saddle 320. Bridge repair reinforcement method characterized in that it comprises a step of tensioning the end of the tension device).